[0001] This invention relates generally to steam turbine buckets (or blades) and, more particularly,
to composite blades designed to provide different predetermined temperature capabilities
in different selected areas of the airfoil portions of the blades.
[0002] For turbine buckets or blades, centrifugal loads are a function of the operating
speed, the mass of the blade, and the radius from engine centerline where that mass
is located. As the mass of the blade increases, the physical area or cross-sectional
area must increase at lower radial heights to be able to carry the mass above it without
exceeding the allowable stresses for the given material. This increasing section area
of the blade at lower spans contributes to excessive flow blockage at the root and
thus lower performance. The weight of the blade contributes to higher disk stresses
and thus to potentially reduced reliability.
[0003] Several prior U.S. patents relate to so-called "hybrid" blade designs where the weight
of the airfoil is reduced by composing the airfoil as a combination of a metal and
polymer filler material. Specifically, one or more pockets are formed in the airfoil
portion and filled with the polymer filler material in such a way that the airfoil
profile is not altered. These prior patents include U.S. Patent Nos. 6,139,278; 6,042,338;
5,931,641 and 5,720,597. See also copending and commonly owned application S.N. 10/249,518
filed April 16, 2003. The '518 application discloses hybrid blades where pocket configurations
are altered to vary the damping characteristics of respective groups of blades.
[0004] Another issue relating to the use of hybrid steam turbine blades, however, relates
to cost as a function of temperatures experienced by such blades during use. In a
double flow steam turbine, for example, there is significant windage heating of the
last stage blade tip area during partial load and full speed conditions. The hood
area behind the blades has a water spray system to cool the exhaust flow to the condenser.
Even during the operation of the water sprays, however, the cooling flow does not
migrate to the heated area near the blade tips, and thus, cooling of the blade tips
is minimal. The blade tips during this condition can reach in excess of 400°F. wherein,
during normal operation, the blade temperatures reach only about 150°F. Accordingly,
most of the current polymers (urethanes and/or rubbers) considered for hybrid bucket
applications are restricted for use at less than 300°F. While there are a few high
temperature polymers available, their cost may be as much as 5X the cost of the lower
temperature polymers.
[0005] This invention expands the hybrid blade concept to include the use of multiple fillers
in a single blade or bucket as a function of required temperature capability. Typically,
the higher temperature material would be used in the outermost radial pockets. Thus,
the more costly and higher temperature capability material may be selected for use
only in a limited area of the airfoil tip while the less expensive material may be
selected in other areas, e.g., the radially inner or lower section of the blade airfoil.
The cost benefit to this arrangement is further enhanced by the fact that a lesser
volume of filler is required in the radially outer portions of the blade.
[0006] In its broader aspects, therefore, the invention relates to a method of manufacturing
a blade for assembly on a steam turbine rotor wheel comprising forming an airfoil
portion with plural pockets and filling said pockets with more than one filler material
chosen as a function of required temperature capability.
[0007] In another aspect, the invention relates to a turbine blade having an airfoil portion
formed with plural pockets filled with respectively different polymer filler materials
chosen as a function of required temperature capability.
[0008] In another aspect, the invention relates to a steam turbine rotor wheel comprising
a row of blades secured about a circumferential periphery of the wheel, each blade
having plural pockets filled with respectively different polymer fill materials chosen
as a function of required temperature capability.
[0009] The invention will now be described in detail in connection with the drawings identified
below.
[0010] The invention will now be described in greater detail, by way of example, with reference
to the drawings, in which:-
FIGURE 1 is a schematic diagram of a double-flow low pressure turbine;
FIGURE 2 is a perspective view of a partially completed hybrid blade in accordance
with an exemplary embodiment of the invention; and
FIGURE 3 is a schematic side elevation of a turbine wheel having a plurality of turbine
blades mounted thereon.
[0011] Figure 1 shows a schematic diagram of a double-flow, low pressure turbine 10 including
a turbine casing 12, rotor 14 and a plurality of wheels in two turbine sections indicated
at 16, 18. The areas 20, 22 circled in dotted lines represent the radially outermost
regions of the last stage blades that have been shown to experience the most windage
heating during partial load conditions. Thus, in accordance with an exemplary embodiment
of the invention, higher temperature filler material (at least 400°F. capability)
is used in radially outer pockets of the blades. Figure 2, for example, shows a blade
24 including a shank portion 26 and an airfoil portion 28. Radially inner and outer
pockets 30, 32 are formed on the pressure side of the airfoil portion 28, separated
by a relatively wide web or rib 34 and a mid-span damper 36. In the example given,
a high temperature filler material 38 is used to fill pocket 32 and a lower temperature
filler material 40 would be used to fill pocket 30. Some stages may require high temperature
filler material only in the outer 10-15% of the airfoil portion, but in any event,
the determination can be made based on test data for particular turbine designs. It
may be that more than two polymer materials be used in as many pockets, successively
from highest temperature material to lowest.
[0012] Figure 3 illustrates schematically a row of blades 24, mounted on a turbine rotor
wheel 42, the blades 24 utilizing plural filler materials 38, 40 as described herein.
[0013] The filler materials 38, 40 may comprise known urethanes, rubber compounds or polymer
mixtures with other materials such as glass or ceramics with different temperature
capabilities. Choices for bonding the filler materials to the metal surface of the
airfoil portion 28 include, without limitation, self adhesion, adhesion between the
filler materials 38, 40 and the metal surface of the airfoil portion 28, adhesive
bonding (adhesive film or paste), and fusion bonding.
[0014] The utilization of different filler materials permits improved temperature capability
of hybrid buckets at reduced cost. Each material used will be formulated for specific
locations on the bucket based on temperature characteristics of the filler materials
and temperature capability requirements of the blades in any given stage. Using the
more expensive, high temperature, materials in a limited location on the bucket will
make the design of hybrid blades more feasible especially for those blades that experience
high windage conditions.
1. A method of manufacturing a blade (24) for assembly on a steam turbine rotor wheel
(42) comprising forming an airfoil portion (28) with plural pockets (30, 32) and filling
said pockets with more than one filler material (40, 38) chosen as a function of required
temperature capability.
2. The method of claim 1 wherein said plural pockets include a radially outer pocket
(32) and a radially inner pocket (30), and wherein the temperature capability of the
filler material (38) in the radially outer pocket (32) is greater than the filler
material (40) in the radially inner pocket (30).
3. The method of claim 2 wherein said greater temperature capability comprises at least
a 400°F. capability.
4. The method of claim 1, 2 or 3 wherein said filler materials (38, 40) comprise polymers.
5. The method of claim 1, 2 or 3 wherein said filler materials (38, 40) comprise urethane
polymers.
6. A turbine blade (24) having an airfoil portion (28) formed with plural pockets (30,
32) filled with respectively different polymer filler materials (40, 38) chosen as
a function of required temperature capability.
7. The turbine blade of claim 6 wherein a radially outermost one (32) of said plural
pockets has a higher temperature capability than other of said plural pockets.
8. The turbine blade of claim 6 wherein said plural pockets (30, 32) include a radially
outer pocket and a radially inner pocket, and wherein the temperature capability of
the filler material in the radially outer pocket is greater than the filler material
in the radially inner pocket.
9. The steam turbine rotor wheel of claim 6, 7 or 8 wherein said polymer filler materials
comprise urethane polymers.
10. A steam turbine rotor wheel comprising a row of blades (24) secured about a circumferential
periphery of the wheel, each blade (24) having plural pockets (30, 32) filled with
respectively different polymer filler materials (40, 38) chosen as a function of required
temperature capability.